THERMOELECTRIC MODULE AND ADJUSTMENT METHOD OF THERMOELECTRIC MODULE

Abstract

A thermoelectric module includes a substrate, a plurality of electrodes arranged on a surface of the substrate, a plurality of thermoelectric elements respectively connected to the plurality of electrodes, and at least three terminals respectively connected to the different electrodes and connected to one or both of a first load and a second load.

Description

FIELD

The present invention relates to a thermoelectric module and an adjustment method of the thermoelectric module.

BACKGROUND

A thermoelectric module that converts thermal energy into electrical energy by the Seebeck effect is known.

CITATION LIST

Patent Literature

Patent Literature 1: Japanese Laid-Open Patent Application No. 2016-164947

SUMMARY

Technical Problem

There is a case where electrical energy generated from a thermoelectric module is distributed to a first load and a second load. For example, in a case where a motor to rotate a fan that cools a thermoelectric module is provided, there is a case where a part of electrical energy generated from the thermoelectric module is supplied to the motor and surplus electrical energy is supplied to an external load. When the electrical energy supplied to the motor is large, the electrical energy supplied to the external load is decreased. When the electrical energy supplied to the motor is small, the thermoelectric module is not sufficiently cooled, and the electrical energy generated from the thermoelectric module is decreased.

An aspect of the present invention is to efficiently supply electrical energy generated from a thermoelectric module to each of a first load and a second load in a case where the electrical energy is distributed to the first load and the second load.

Solution to Problem

According to an aspect of the present invention, a thermoelectric module comprises: a substrate; a plurality of electrodes arranged on a surface of the substrate; a plurality of thermoelectric elements respectively connected to the plurality of electrodes; and at least three terminals respectively connected to the different electrodes and connected to one or both of a first load and a second load.

Advantageous Effects of Invention

According to an aspect of the present invention, in a case where electrical energy generated from a thermoelectric module is distributed to a first load and a second load, the electrical energy can be efficiently supplied to each of the first load and the second load.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic diagram illustrating an example of a thermoelectric device according to a first embodiment.

FIG. 2 is a schematic diagram illustrating a thermoelectric module according to the first embodiment.

FIG. 3 is a plan view illustrating an example of a first substrate according to the first embodiment.

FIG. 4 is a schematic diagram illustrating a connection form between terminals and a first load and a second load according to the first embodiment.

FIG. 5 is a plan view illustrating a first terminal according to the first embodiment.

FIG. 6 is a plan view illustrating a second terminal according to the first embodiment.

FIG. 7 is a schematic diagram illustrating thermal resistance of the thermoelectric device according to the first embodiment.

FIG. 8 is a flowchart illustrating an example of an adjustment method the thermoelectric module according to the first embodiment.

FIG. 9 is a block diagram illustrating a computer system according to the first embodiment.

FIG. 10 is a view illustrating a relationship between a voltage applied to a motor and air volume generated by a fan according to the first embodiment.

FIG. 11 is a view illustrating a relationship between air volume applied to a heat radiating member and thermal resistance of the heat radiating member according to the first embodiment.

FIG. 12 is a view illustrating a relationship between the voltage applied to the motor and the thermal resistance of the heat radiating member according to the first embodiment.

FIG. 13 is a view illustrating a relationship between the voltage applied to the motor and effective output according to the first embodiment.

FIG. 14 is a plan view illustrating an example of a first substrate according to a second embodiment.

DESCRIPTION OF EMBODIMENTS

In the following, embodiments according to the present invention will be described with reference to the drawings. However, the present invention is not limited to this. Components of the embodiments described in the following can be arbitrarily combined. Also, there is a case where a part of the components is not used.

In the following description, an XYZ Cartesian coordinate system is set, and a positional relationship of each part will be described with reference to this XYZ Cartesian coordinate system. It is assumed that a direction parallel to an X-axis in a predetermined plane is an X-axis direction (first axis direction), a direction parallel to a Y-axis orthogonal to the X-axis in the predetermined plane is a Y-axis direction (second axis direction), and the predetermined surface, and a direction parallel to a Z-axis orthogonal to the predetermined plane is a Z-axis direction (third-axis direction). The X-axis direction, the Y-axis direction, and the Z-axis direction are orthogonal to each other. An XY plane including the X-axis and Y-axis is parallel to the predetermined plane. A YZ plane including the Y-axis and the Z-axis is orthogonal to the XY plane. An XZ plane including the X-axis and the Z-axis is orthogonal to each of the XY plane and YZ plane.

First Embodiment

<Thermoelectric Device>

FIG. 1 is a schematic diagram illustrating an example of a thermoelectric device 1 according to the present embodiment. The thermoelectric device 1 includes a thermoelectric module 2, a heat absorbing member 3 connected to an end surface 21T on a −Z side of the thermoelectric module 2, a heat radiating member 4 connected to an end surface 22T on a +Z side of the thermoelectric module 2, a fan 5 arranged on the +Z side of the heat radiating member 4, and a second load 6 that generates power to rotate the fan 5.

The thermoelectric module 2 generates electrical energy by using the Seebeck effect. The thermoelectric module 2 generates electrical energy when the end surface 21T on the −Z side of the thermoelectric module 2 is heated and the end surface 22T on the +Z side of the thermoelectric module 2 is cooled.

FIG. 2 is a schematic diagram illustrating the thermoelectric module 2 according to the present embodiment. The thermoelectric module 2 includes a first substrate 21, a second substrate 22, a plurality of electrodes 23 arranged on a surface 21S of the first substrate 21, a plurality of electrodes 24 arranged on a surface 22S of the second substrate 22, and a plurality of thermoelectric elements 25 respectively connected to the plurality of electrodes 23 and the plurality of electrodes 24.

Each of the first substrate 21 and the second substrate 22 is formed of an electrical insulating material such as ceramics or polyimide. The first substrate 21 is arranged on the −Z side of the thermoelectric elements 25. The second substrate 22 is arranged on the +Z side of the thermoelectric elements 25. The first substrate 21 has a surface 21S facing the +Z side and an end surface 21T facing the −Z side. Each of the surface 21S and the end surface 21T of the first substrate 21 is parallel to the XY plane. The second substrate 22 has a surface 22S facing the −Z side and an end surface 22T facing the +Z side. Each of the surface 22S and the end surface 22T of the second substrate 22 is parallel to the XY plane. The end surface 21T of the first substrate 21 includes the end surface 21T of the thermoelectric module 2. The end surface 22T of the second substrate 22 includes the end surface 22T of the thermoelectric module 2.

The plurality of electrodes 23 is arranged in a matrix on the surface 21S of the first substrate 21. The plurality of electrodes 24 is arranged in a matrix on the surface 22S of the second substrate 22.

The thermoelectric elements 25 include, for example, a BiTe-based thermoelectric material. The thermoelectric elements 25 include an n-type thermoelectric semiconductor element 25N and a p-type thermoelectric semiconductor element 25P. The n-type thermoelectric semiconductor element 25N and the p-type thermoelectric semiconductor element 25P are alternately arranged in the XY plane. The electrodes 23 are respectively connected to an end surface on the −Z side of the n-type thermoelectric semiconductor element 25N and an end surface on the −Z side of the p-type thermoelectric semiconductor element 25P. The electrodes 24 are respectively connected to an end surface on the +Z side of the n-type thermoelectric semiconductor element 25N and an end surface on the +Z side of the p-type thermoelectric semiconductor element 25P.

When the first substrate 21 is heated and the second substrate 22 is cooled, a temperature difference is given between the end surface on the −Z side and the end surface on the +Z side of each of the n-type thermoelectric semiconductor element 25N and the p-type thermoelectric semiconductor element 25P. When the temperature difference is given between the end surface on the −Z side and the end surface on the +Z side of the n-type thermoelectric semiconductor element 25N, electrons move from the end surface on the −Z side toward the end surface on the +Z side in the n-type thermoelectric semiconductor element 25N. When the temperature difference is given between the end surface on the −Z side and the end surface on the +Z side of the p-type thermoelectric semiconductor element 25P, holes move from the end surface on the −Z side toward the end surface on the +Z side in the p-type thermoelectric semiconductor element 25P. The n-type thermoelectric semiconductor element 25N and the p-type thermoelectric semiconductor element 25P are connected in series via the electrodes 23 and the electrodes 24. The electrons and holes generate a potential difference between the electrodes 23 and the electrodes 24. The thermoelectric module 2 generates electrical energy due to the generation of the potential difference between the electrodes 23 and the electrodes 24.

The heat absorbing member 3 receives heat from a heat source and performs transmission thereof to the thermoelectric module 2. The heat absorbing member 3 is formed of a metal material such as aluminum or copper. The heat absorbing member 3 is connected to the end surface 21T of the thermoelectric module 2.

The heat radiating member 4 takes heat from the thermoelectric module 2. The heat radiating member 4 is formed of a metal material such as aluminum. The heat radiating member 4 is arranged between the thermoelectric module 2 and the fan 5 in the Z-axis direction.

The heat radiating member 4 includes a heatsink. The heat radiating member 4 has a heat radiating plate 4P connected to the end surface 22T of the thermoelectric module 2, and a fin 4F supported by the heat radiating plate 4P. The pin 4F is a pin fin. Note that the fin 4F may be a plate fin.

The fan 5 rotates to circulate air around the heat radiating member 4 and cool the end surface 22T of the thermoelectric module 2. The fan 5 is arranged on the +Z side of the thermoelectric module 2 and the heat radiating member 4. By the rotation of the fan 5, the heat radiating member 4 and the second substrate 22 are cooled.

The motor 6 generates power to rotate the fan 5. The fan 5 is rotated when the motor 6 is driven. By the rotation of the fan 5, air circulates around the heat radiating member 4, and heat radiation by the heat radiating member 4 is promoted. The second substrate 22 is cooled by the heat radiation by the heat radiating member 4.

The electrical energy generated from the thermoelectric module 2 is distributed to a first load and a second load. In the present embodiment, the first load is an external load 7 provided outside the thermoelectric device 1. The second load is the motor 6. The motor 6 is driven by the electrical energy generated from the thermoelectric module 2. The thermoelectric device 1 is an autonomous thermoelectric device that drives the motor 6 provided in the thermoelectric device 1 by the electrical energy generated from the thermoelectric module 2.

In the following description, the external load 7 is arbitrarily referred to as the first load 7, and the motor 6 is arbitrarily referred to as the second load 6.

<Terminal>

FIG. 3 is a plan view illustrating an example of a first substrate 21 according to the present embodiment. As illustrated in FIG. 3, a thermoelectric module 2 includes a first substrate 21, and a plurality of electrodes 23 arranged on a surface 21S of the first substrate 21. A thermoelectric element 25 is connected to each of the plurality of electrodes 23. The plurality of electrodes 23 is connected in series via the plurality of thermoelectric elements 25.

In the XY plane, an outer shape of the first substrate 21 is a quadrangle. The first substrate 21 has four edge portions 21E. The edge portions 21E include a pair of first edge portions 21EX extending in the X-axis direction, and a pair of second edge portions 21EY extending in the Y-axis direction.

In the XY plane, an outer shape of each electrode 23 is a quadrangle. Shapes and sizes of the plurality of electrodes 23 are equal. The plurality of electrodes 23 is arranged in a matrix on the surface 21S of the first substrate 21. The electrodes 23 are arranged at regular intervals in each of the X-axis direction and the Y-axis direction.

The thermoelectric module 2 includes at least three terminals 8 respectively connected to the different electrodes 23 and connected to one or both of the first load 7 and the second load 6. The terminals 8 are arranged between the electrodes 23 and the edge portions 21E of the first substrate 21 on the surface 21S of the first substrate 21. In the present embodiment, the terminals 8 are arranged between an electrode 23 on the most −Y side among the plurality of electrodes 23 arranged in the Y-axis direction and a first edge portion 21EX of the first substrate 21 on the −Y side.

In the present embodiment, the terminals 8 include a first terminal 81 connected to the first load 7, a second terminal 82 connected to each of the first load 7 and the second load 6, and a third terminal 83 connected to the second load 6.

The first terminal 81, the second terminal 82, and the third terminal 83 are arranged in the X-axis direction between the electrodes 23 and the first edge portions 21EX.

The first terminal 81 is connected to an electrode 23 on the most +X side among the plurality of electrodes 23 arranged in the X-axis direction. The second terminal 82 is connected to an electrode 23 on the most -X side among the plurality of electrodes 23 arranged in the X-axis direction. The third terminal 83 is arranged between the first terminal 81 and the second terminal 82 in the X-axis direction. That is, the third terminal 83 is connected to an electrode 23 between the electrode 23 to which the first terminal 81 is connected and the electrode 23 to which the second terminal 82 is connected.

FIG. 4 is a schematic diagram illustrating a connection form between the terminals 8 and the first load 7 and the second load 6 according to the present embodiment. As illustrated in FIG. 3 and FIG. 4, the first terminal 81 is a positive terminal. The second terminal 82 is a negative terminal. The third terminal 83 is a positive terminal. The first terminal 81 is connected to the first load 7 via a lead wire 11. The first terminal 81 is not connected to the second load 6. The second terminal 82 is connected to both of the first load 7 and the second load 6 via a lead wire 12. The third terminal 83 is connected to the second load 6 via a lead wire 13. The third terminal 83 is not connected to the first load 7. A voltage V_el between the first terminal 81 and the second terminal 82 is higher than a voltage V_fan between the second terminal 82 and the third terminal 83. The voltage V_el is a voltage applied to the first load 7. The voltage V_fan is a voltage applied to the second load 6.

As illustrated in FIG. 3, the third terminal 83 includes a plurality of third terminals 83A, 83B, and 83C respectively connected to the different electrodes 23. Among three electrodes 23 connected to the third terminals 83A, 83B, and 83C, an electrode 23 connected to the third terminal 83A is the farthest from the electrode 23 connected to the second terminal 82, and an electrode 23 connected to the third terminal 83C is the closest to the electrode 23 connected to the second terminal 82. The voltage V_fan is adjusted by selection of a third terminal 83 connected to the lead wire 13 from the plurality of third terminals 83A, 83B, and 83C. When the lead wire 13 is connected to the third terminal 83A, the voltage V_fan is adjusted to a high voltage. When the lead wire 13 is connected to the third terminal 83C, the voltage V_fan is adjusted to a low voltage. When the lead wire 13 is connected to the third terminal 83B, the voltage V_fan is adjusted to an intermediate voltage.

In the present embodiment, the first terminal 81 and the third terminal 83 that are positive terminals are arranged on a +X side of a center of the first substrate 21 in the X-axis direction. The second terminal 82 is arranged on a −X side of the center of the first substrate 21 in the X-axis direction.

FIG. 5 is a plan view illustrating the first terminal 81 according to the present embodiment. As illustrated in FIG. 5, the first terminal 81 that is a positive terminal includes a first portion 71 protruding from the electrode 23 toward a first edge portion 21EX, a second portion 72 connected to a tip portion on the −Y side of the first portion 71 and extending in the X-axis direction between the electrode 23 and the first edge portion 21EX, and a third portion 73 protruding from the second portion 72 toward the first edge portion 21EX. The second portion 72 of the first terminal 81 protrudes from the tip portion of the first portion 71 toward the center in the X-axis direction of the first substrate 21.

The third terminal 83 that is a positive terminal has a shape similar to that of the first terminal 81. That is, the third terminal 83 also includes a first portion 71 protruding from the electrode 23 toward the first edge portion 21EX, a second portion 72 connected to a tip portion on the −Y side of the first portion 71 and extending in the X-axis direction between the electrode 23 and the first edge portion 21EX, and a third portion 73 protruding from the second portion 72 toward the first edge portion 21EX. The second portion 72 of the third terminal 83 protrudes from the tip portion of the first portion 71 toward the center in the X-axis direction of the first substrate 21.

FIG. 6 is a plan view illustrating the second terminal 82 according to the present embodiment. As illustrated in FIG. 6, the second terminal 82 that is a negative terminal includes a first portion 71 protruding from the electrode 23 toward the first edge portion 21EX, a second portion 72 connected to a tip portion on the −Y side of the first portion 71 and extending in the X-axis direction between the electrode 23 and the first edge portion 21EX, and a third portion 73 protruding from the second portion 72 toward the first edge portion 21EX. The second portion 72 of the second terminal 82 protrudes from the tip portion of the first portion 71 toward the center in the X-axis direction of the first substrate 21.

<Adjustment Method of Thermoelectric Module>

Next, the adjustment method the thermoelectric module 2 will be described. Note that the adjustment method described in the following is an example, and the present disclosure is not limited thereto. As described above, in the present embodiment, the electrical energy generated from the thermoelectric module 2 is distributed to the first load 7 (external load) and the second load 6 (motor). When it is assumed that power generation output indicating electrical energy generated by the thermoelectric module 2 is Pg, effective output indicating electrical energy distributed to the first load 7 is Pe, and power consumption indicating electrical energy distributed to the second load 6 is Pf, an equation (1) is satisfied.

P_e=P_g−P_f   (1)

In the present embodiment, adjusting the thermoelectric module 2 includes determining a voltage V_fan that maximizes the effective output Pe. In the following description, the voltage V_fan that maximizes the effective output Pe is arbitrarily referred to as an optimum voltage V_{fan_op}. Note that the optimum voltage V_{fan_op} does not have to be the voltage V_fan that maximizes the effective output Pe, and may be a voltage V_fan that causes the effective output Pe to be equal to or larger than a predetermined value.

FIG. 7 is a schematic diagram illustrating thermal resistance of the thermoelectric device 1 according to the present embodiment. As illustrated in FIG. 7, the heat absorbing member 3, the thermoelectric module 2, and the heat radiating member 4 are connected in series. It is assumed that a temperature of a heat source that heats the thermoelectric module 2 is T_s. It is assumed that a temperature of an atmospheric space around the thermoelectric module 2 is T_a. It is assumed that thermal resistance of the heat absorbing member 3 is R_h. It is assumed that thermal resistance of the thermoelectric module 2 is R_m. It is assumed that thermal resistance of the heat radiating member 4 is R_c. It is assumed that a temperature of an end surface 21T on a high temperature side of the thermoelectric module 2 connected to the heat absorbing member 3 is T_hj. It is assumed that a temperature of an end surface 22T on a low temperature side of the thermoelectric module 2 connected to the heat radiating member 4 is T_cj. It is assumed that a penetration heat amount of the thermoelectric device 1 from the heat source including the heat absorbing member 3, the thermoelectric module 2, and the heat radiating member 4 to the atmospheric space is Q_n.

FIG. 8 is a flowchart illustrating an example of the adjustment method of the thermoelectric module 2 according to the present embodiment. The adjustment method of the thermoelectric module 2 includes a determination method the optimum voltage V_{fan_op}.

FIG. 9 is a block diagram illustrating a computer system 1000 according to the present embodiment. The computer system 1000 includes a processor 1001 such as a central processing unit (CPU), a main memory 1002 including a non-volatile memory such as a read only memory (ROM) and a volatile memory such as a random access memory (RAM), a storage 1003, and an interface 1004 including an input/output circuit. The computer system 1000 determines the optimum voltage V_{fan_op}. A program to determine the optimum voltage V_{fan_op} is stored in the storage 1003. The processor 1001 reads the program from the storage 1003, develops the program in the main memory 1002, and determines the optimum voltage V_{fan_op} according to the program. Note that the program may be distributed to the computer system 1000 through a network.

The processor 1001 acquires correlation data between the voltage V_fan applied to the second load 6 and the thermal resistance R_c of the heat radiating member 4 (Step S1).

In the present embodiment, the correlation data between the voltage V_fan and the thermal resistance R_c of the heat radiating member 4 includes a relational expression indicating a relationship between the voltage V_fan and the thermal resistance R_c of the heat radiating member 4.

FIG. 10 is a view illustrating a relationship between a voltage V_fan applied to the second load 6 and air volume F_fan generated by the fan 5 according to the present embodiment. FIG. 11 is a view illustrating a relationship between air volume F_fan applied to the heat radiating member 4 and thermal resistance R_c of the heat radiating member 4 according to the present embodiment.

In FIG. 10, a horizontal axis indicates the voltage V_fan [V] applied to the second load 6, and a vertical axis indicates the air volume F_fan [m³/min] generated by the fan 5 when the voltage V_fan is applied to the second load 6. In FIG. 11, a horizontal axis indicates the air volume F_fan applied to the heat radiating member 4, and a vertical axis indicates the thermal resistance R_c [K/W] of the heat radiating member 4 of when the air volume F_fan is applied.

An equation (2) is satisfied between the voltage V_fan applied to the second load 6 and the air volume F_fan generated by the fan 5 when the voltage V_fan is applied to the second load 6. In the equation (2), a is a constant.

F_fan=a×V_fan   (2)

An equation (3) is satisfied between the air volume F_fan applied from the fan 5 to the heat radiating member 4 and the thermal resistance R_c of the heat radiating member 4 of when the air volume F_fan is applied. In the equation (3), b and c are constants.

R_c=b×F_fan^−c   (3)

FIG. 10 is a graph of the equation (2). FIG. 11 is a graph of the equation (3).

FIG. 12 is a view illustrating a relationship between a voltage V_fan applied to the second load 6 and thermal resistance R_c of the heat radiating member 4 according to the present embodiment. In FIG. 12, a horizontal axis indicates the voltage V_fan [V] applied to the second load 6, and a vertical axis indicates the thermal resistance R_c [K/W] of the heat radiating member 4 of when the voltage V_fan is applied to the second load 6. From the equation (2) and the equation (3), an equation (4) is satisfied between the voltage V_fan applied to the second load 6 and the thermal resistance R_c of the heat radiating member 4 of when the voltage V_fan is applied to the second load 6.

R_c=a^−c×b×V_fan^−c   (4)

FIG. 12 is a graph of the equation (4).

Correlation data including the relational expression between the voltage V_fan and the thermal resistance R_c indicated in the equation (4) is stored in advance in the storage 1003. The processor 1001 acquires the relational expression between the voltage V_fan and the thermal resistance R_c indicated in the equation (4) from the storage 1003 as the correlation data between the voltage V_fan and the thermal resistance R_c.

After acquiring the correlation data between the voltage V_fan and the thermal resistance R_c, the processor 1001 sets the voltage V_fan to an initial value (Step S2).

After the voltage V_fan is set to the initial value, the processor 1001 calculates the power consumption Pf on the basis of the voltage V_fan applied to the second load 6 and a current I_fan that flows in the second load 6 when the voltage V_fan is applied (Step S3).

A relationship between the voltage V_fan applied to the second load 6 and the current I_fan that flows in the second load 6 when the voltage V_fan is applied is known data that can be derived from specification data of the second load 6, and is stored in advance in the storage 1003. Note that the relationship between the voltage V_fan and the current I_fan may be derived, for example, by a preliminary experiment or simulation. The processor 1001 calculates the power consumption Pf on the basis of an equation (5).

P_f=I_fan×V_fan   (5)

The processor 1001 calculates a temperature T_hj of the end surface 21T on the high temperature side and a temperature T_cj of the end surface 22T on the low temperature side of the thermoelectric module 2 on the basis of the thermal resistance R_h of the heat absorbing member 3, the thermal resistance R_m of the thermoelectric module 2, the thermal resistance R_c of the heat radiating member 4, the temperature T_s of the heat source, and the temperature T_a of the atmospheric space (Step S4).

Generally, when a temperature difference between both end surfaces of an object having thermal resistance R is ΔT, a penetration heat amount Q of the object is expressed by an equation (6).

$\begin{array}{cc}Q=\frac{\Delta T}{R}& \left(6\right)\end{array}$

Thus, a penetration heat amount Q_n of the thermoelectric device 1 is calculated on the basis of an equation (7). Also, a temperature T_hjn+1 on the high temperature side and a temperature T_cjn+1 on the low temperature side of the thermoelectric module 2 are calculated on the basis of an equation (8) and an equation (9).

$\begin{array}{cc}{Q}_n=\frac{T_s-T_a}{R_h+R_m\left(T_{\mathrm{hjn}},T_{\mathrm{cjn}}\right)+R_c}& \left(7\right)\\ T_{\mathrm{hjn}+1}=T_s-Q_n\times R_h& \left(8\right)\\ T_{\mathrm{cjn}+1}=T_a+Q_n\times R_c& \left(9\right)\end{array}$

In the equation (7) and the equation (9), the thermal resistance R_c is calculated by substitution of the initial value of the voltage V_fan set in Step S2 into the equation (4). In the equation (7), the thermal resistance R_m is calculated on the basis of an equation (10) and an equation (11).

$\begin{array}{cc}{T}_m=\frac{T_{\mathrm{hjn}}+T_{\mathrm{cjn}}}{2}& \left(10\right)\\ R_m=a\times T_m^3+b\times T_m^2+c\times T_m+d& \left(11\right)\end{array}$

As indicated in the equation (10), a temperature T_m is an average value of the temperature T_hj of the end surface 21T on the high temperature side and the temperature T_cj of the end surface 22T on the low temperature side of the thermoelectric module 2. In the equation (11), each of a constant a, a constant b, a constant c, and a constant d is a unique value determined according to a material of the thermoelectric element 25. As indicated in the equation (11), the thermal resistance R_m of the thermoelectric module 2 is a function of the temperature T_m (temperature T_hj and temperature T_cj).

The processor 1001 executes an operation [T_hjn+1−T_hjn] and an operation [T_cjn+1−T_cjn] and determines whether a value of [T_hjn+1−T_hjn] and a value of [T_cjn+1−T_cjn] are approximate to 0 (Step S5).

The processor 1001 determines that the value of [T_hjn+1−T_hjn] is approximate to 0 in a case where a difference between the value of [T_hjn+1−T_hjn] and 0 is equal to or smaller than a predetermined threshold. In a case where a difference between the value of [T_cjn+1−T_cjn] and 0 is equal to or smaller than a predetermined threshold, the processor 1001 determines that the value of [T_cjn+1−T_cjn] is approximate to 0.

Note that in the first operation, an initial value T_hj0 is given to the temperature T_hjn on the high temperature side, and an initial value T_cj0 is given to the temperature T_cjn on the low temperature side. Each of the initial value T_hj0 and the initial value T_cj0 is an arbitrary value.

In a case where it is determined in Step S5 that the value of [T_hjn+1−T_hjn] and the value of [T_cjn+1−T_cjn] are not approximate to 0 (Step S5: No), the processor 1001 returns to the processing in Step S4. The processor 1001 repeats the above processing until it is determined that the value of [T_hjn+1−T_hjn] and the value of [T_cjn+1−T_cjn] are approximate to 0.

In a case where it is determined in Step S5 that the value of [T_hjn+1−T_hjn] and the value of [T_cjn+1−T_cjn] are approximate to 0 (Step S5: Yes), the processor 1001 calculates power generation output Pg on the basis of the temperature T_hjn and the temperature T_cjn of when the value of [T_hjn+1−T_hjn] and the value of [T_cjn+1−T_cjn] are approximate to 0 (Step S6).

The power generation output Pg is calculated on the basis of an equation (12). In the equation (12), a constant A is a unique constant determined on the basis of a material of the thermoelectric element 25.

P_g=A(T_hjn−T_cjn)²   (12)

The processor 1001 calculates effective output Pe on the basis of the power consumption Pf calculated in Step S3 and the power generation output Pg calculated in Step S7. That is, the processor 1001 calculates the effective output Pe on the basis of the equation (1) (Step S7).

From the above, the effective output Pe of when the voltage V_fan is the initial value is calculated. The processor 1001 changes the voltage V_fan to an arbitrary value and executes the processing from Step S3 to Step S7. That is, the processor 1001 sequentially changes the voltage V_fan, and executes the processing from Step S3 to Step S7 for each of the plurality of voltages V_fan.

The processor 1001 determines whether to end the change of the voltage V_fan (Step S8).

In a case where it is determined in Step S8 that the change of the voltage V_fan is not to be ended (Step S8: No), the processor 1001 executes the processing from Step S3 to Step S7 after changing the voltage V_fan (Step S9).

FIG. 13 is a view illustrating a relationship between a voltage V_fan applied to the second load 6 and effective output Pe according to the present embodiment. In FIG. 13, a horizontal axis indicates the voltage V_fan applied to the second load 6, and a vertical axis indicates the effective output Pe of when the voltage V_fan is applied to the second load 6. The processor 1001 sequentially changes the voltage V_fan, executes the processing from Step S3 to Step S7, and calculates the effective output Pe of when the voltage V_fan is applied to the motor 10. In the example illustrated in FIG. 13, effective output Pe of when each of voltages V_{fan_1}, V_{fan_2}, V_{fan_3}, V_{fan_4}, and V_{fan_5} is applied to the second load 6 is calculated.

In a case where it is determined in Step S8 that the change of the voltage V_fan is to be ended (Step S8: Yes), the processor 1001 determines an optimum voltage V_{fan_op} that maximizes the effective output Pe from the relationship between the voltage V_fan and the effective output Pe illustrated in FIG. 13 (Step S9).

That is, the processor 1001 determines the optimum voltage V_{fan_op} applied to the second load 6 on the basis of a plurality of kinds of effective output Pe calculated by sequential changing of the voltage V_fan applied to the second load 6. In the example illustrated in FIG. 13, the voltage V_{fan_3} that maximizes the effective output Pe is determined as an optimum voltage _{fan_op}.

<Effect>

As described above, according to the present embodiment, at least three terminals 8 respectively connected to different electrodes 23 are provided. The terminals 8 are connected to one or both of a first load 7 and a second load 6 via lead wires. Thus, in a case where electrical energy generated from a thermoelectric module 2 is distributed to the first load 7 and the second load 6, the electrical energy can be efficiently supplied to each of the first load 7 and the second load 6.

The terminals 8 are arranged between electrodes 23 and edge portions 21E of a first substrate 21 on a surface 21S of a first substrate 21. Thus, connection between the terminals 8 and the lead wires can be smoothly executed.

The terminals 8 include a first terminal 81 connected only to the first load 7, a second terminal 82 connected to both of the first load 7 and the second load 6, and a third terminal 83 connected only to the second load 6. Thus, the electrical energy can be efficiently supplied to each of the first load 7 and the second load 6 in a state in which the number of terminals 8 is controlled.

The first substrate has first edge portions 21EX extending in the X-axis direction. The first terminal 81, the second terminal 82, and the third terminal 83 are arranged in the X-axis direction between the electrodes 23 and the first edge portions 21EX. Thus, the first terminal 81, the second terminal 82, and the third terminal 83 can be smoothly connected to a lead wire 11, a lead wire 12, and a lead wire 13, respectively.

The third terminal 83 is arranged between the first terminal 81 and the second terminal 82 in the X-axis direction. Thus, a voltage V_el applied to the first load 7 can be made higher than a voltage V_fan applied to the second load 6.

Each of the terminals 8 includes a first portion 71 protruding from an electrode 23 toward a first edge portion 21EX, a second portion 72 connected to a tip portion of the first portion 71 and extending in the X-axis direction between the electrode 23 and the first edge portion 21EX, and a third portion 73 protruding from the second portion 72 toward the first edge portion 21EX. In the X-axis direction, the first terminal 81 and the third terminal 83 that are positive terminals are arranged on a +X side of a center of the first substrate 21, and the second terminal 82 that is a negative terminal is arranged on a −X side of the center of the first substrate 21. The second portion 72 of each of the first terminal 81, the second terminal 82, and the third terminal 83 protrudes from the tip portion of the first portion 71 toward the center of the first substrate 21. Thus, an operator can distinguish whether a terminal 8 is a positive terminal or a negative terminal on the basis of a shape of the terminal 8. That is, the operator can visually distinguish whether the terminal 8 is a positive terminal or a negative terminal.

An optimum voltage V_{fan_op} that maximizes effective output Pe is determined on the basis of a plurality of kinds of effective output Pe calculated by sequential changing of the voltage V_fan applied to the second load 6. Thus, the electrical energy generated from the thermoelectric module 2 can be efficiently distributed to the first load 7 and the second load 6.

Second Embodiment

The second embodiment will be described. In the following description, the same sign is assigned to a configuration element identical or equivalent to that of the above-described embodiment, and a description thereof is simplified or omitted.

FIG. 14 is a plan view illustrating an example of a first substrate 21 according to the present embodiment. As illustrated in FIG. 14, terminals 8 include a first terminal 81 connected to a first load 7, a second terminal 82 connected to the first load 7, a third terminal 83 connected to a second load 6, and a fourth terminal 84 connected to the second load 6. The first terminal 81 is connected to the first load 7 via a lead wire 11. The second terminal 82 is connected to the first load 7 via a lead wire 12. The third terminal 83 is connected to the second load 6 via a lead wire 13. The fourth terminal 84 is connected to the second load 6 via a lead wire 14.

The first terminal 81 and the third terminal 83 are positive terminals. The second terminal 82 and the fourth terminal 84 are negative terminals. In an X-axis direction, the first terminal 81 and the third terminal 83 are arranged on a +X side of a center of the first substrate 21, and the second terminal 82 and the fourth terminal 84 are arranged on a −X side of the center of the first substrate 21.

Similarly to the above-described embodiment, the first substrate 21 has a first edge portion 21EX extending in the X-axis direction. The first terminal 81, the second terminal 82, the third terminal 83, and a fourth terminal 94 are arranged in the X-axis direction between electrodes 23 and the first edge portion 21EX.

The third terminal 83 and the fourth terminal 84 are arranged between the first terminal 81 and the second terminal 82 in the X-axis direction.

Each of the first terminal 81, the second terminal 82, the third terminal 83, and the fourth terminal 84 includes a first portion 71 protruding from an electrode 23 toward the first edge portion 21EX, a second portion 72 connected to a tip portion on a −Y side of the first portion 71 and extending in the X-axis direction between the electrode 23 and the first edge portion 21EX, and a third portion 73 protruding from the second portion 72 toward the first edge portion 21EX.

The second portion 72 of each of the first terminal 81, the second terminal 82, the third terminal 83, and the fourth terminal 84 protrudes from the tip portion of the first portion 71 toward the center in the X-axis direction of the first substrate 21.

As described above, in a case where electrical energy generated from a thermoelectric module 2 is distributed to the first load 7 and the second load 6, the electrical energy can be efficiently supplied to each of the first load 7 and the second load 6 also in the present embodiment.

The first substrate 21 has the first edge portion 21EX extending in the X-axis direction. The first terminal 81, the second terminal 82, the third terminal 83, and the fourth terminal 84 are arranged in the X-axis direction between the electrodes 23 and the first edge portion 21EX. Thus, the first terminal 81, the second terminal 82, the third terminal 83, and the fourth terminal 84 can be smoothly connected to the lead wire 11, the lead wire 12, the lead wire 13, and the lead wire 14, respectively.

The third terminal 83 and the fourth terminal 84 are arranged between the first terminal 81 and the second terminal 82 in the X-axis direction. That is, each of the third terminal 83 and the fourth terminal 84 is connected to an electrode 23 between an electrode 23 to which the first terminal 81 is connected and an electrode 23 to which the second terminal 82 is connected. Thus, a voltage V_el applied to the first load 7 can be made higher than a voltage V_fan applied to the second load 6.

Each of the terminals 8 includes a first portion 71 protruding from an electrode 23 toward the first edge portion 21EX, a second portion 72 connected to a tip portion of the first portion 71 and extending in the X-axis direction between the electrode 23 and the first edge portion 21EX, and a third portion 73 protruding from the second portion 72 toward the first edge portion 21EX. In the X-axis direction, the first terminal 81 and the third terminal 83 that are positive terminals are arranged on the +X side of the center of the first substrate 21, and the second terminal 82 and the fourth terminal 84 that are negative terminals are arranged on the −X side of the center of the first substrate 21. The second portion 72 of each of the first terminal 81, the second terminal 82, the third terminal 83, and the fourth terminal 84 protrudes from the tip portion of the first portion 71 toward the center of the first substrate 21. Thus, an operator can distinguish whether a terminal 8 is a positive terminal or a negative terminal on the basis of a shape of the terminal 8. That is, the operator can visually distinguish whether the terminal 8 is a positive terminal or a negative terminal.

Different Embodiment

Note that in the above-described embodiments, the first load 7 is an external load, and the second load 6 is a motor that rotates the fan 5. For example, both of a first load 7 and a second load 6 may be external loads arranged outside a thermoelectric device 1. Application to a form having three or more loads is also possible.

Note that in the above-described embodiments, one or both of a heat absorbing member 3 and a heat radiating member 4 may be omitted.

REFERENCE SIGNS LIST

1 THERMOELECTRIC DEVICE

2 THERMOELECTRIC MODULE

3 HEAT ABSORBING MEMBER

4 HEAT RADIATING MEMBER

4F FIN

4P HEAT RADIATING PLATE

5 FAN

6 MOTOR

7 EXTERNAL LOAD

8 TERMINAL

11 LEAD WIRE

12 LEAD WIRE

13 LEAD WIRE

14 LEAD WIRE

21 FIRST SUBSTRATE

21E EDGE PORTION

21EX FIRST EDGE PORTION

21EY SECOND EDGE PORTION

21S SURFACE

21T END SURFACE

22 SECOND SUBSTRATE

22S SURFACE

22T END SURFACE

23 ELECTRODE

24 ELECTRODE

25 THERMOELECTRIC ELEMENT

25N n-TYPE THERMOELECTRIC SEMICONDUCTOR ELEMENT

25P p-TYPE THERMOELECTRIC SEMICONDUCTOR ELEMENT

71 FIRST PORTION

72 SECOND PORTION

73 THIRD PORTION

81 FIRST TERMINAL

82 SECOND TERMINAL

83 THIRD TERMINAL

83A THIRD TERMINAL

83B THIRD TERMINAL

83C THIRD TERMINAL

84 FOURTH TERMINAL

Claims

1. A thermoelectric module comprising:

a substrate;

a plurality of electrodes arranged on a surface of the substrate;

a plurality of thermoelectric elements respectively connected to the plurality of electrodes; and

at least three terminals respectively connected to the different electrodes and connected to one or both of a first load and a second load.

2. The thermoelectric module according to claim 1, wherein the terminals are arranged, on the surface of the substrate, between the electrodes and an edge portion of the substrate.

3. The thermoelectric module according to claim 1, wherein the terminals include:

a first terminal connected to the first load,

a second terminal connected to each of the first load and the second load, and

a third terminal connected to the second load.

4. The thermoelectric module according to claim 3, wherein

the substrate has a first edge portion extending in a first axis direction, and

the first terminal, the second terminal, and the third terminal are arranged in the first axis direction between the electrodes and the first edge portion.

5. The thermoelectric module according to claim 4, wherein the third terminal is arranged between the first terminal and the second terminal in the first axis direction.

6. The thermoelectric module according to claim 5, wherein

each of the terminals includes a first portion protruding from one of the electrodes toward the first edge portion, a second portion connected to a tip portion of the first portion and extending in the first axis direction between the electrode and the first edge portion, and a third portion protruding from the second portion toward the first edge portion,

the first terminal and the third terminal are arranged on one side of a center of the substrate and the second terminal is arranged on the other side of the center of the substrate in the first axis direction, and

the second portion of each of the first terminal, the second terminal, and the third terminal protrudes from the tip portion of the first portion toward the center of the substrate.

7. The thermoelectric module according to claim 1, wherein the terminals include:

a first terminal connected to the first load,

a second terminal connected to the first load,

a third terminal connected to the second load, and

a fourth terminal connected to the second load.

8. The thermoelectric module according to claim 7, wherein

the substrate has a first edge portion extending in a first axis direction, and

the first terminal, the second terminal, the third terminal, and the fourth terminal are arranged in the first axis direction between the electrodes and the first edge portion.

9. The thermoelectric module according to claim 8, wherein the third terminal and the fourth terminal are arranged between the first terminal and the second terminal in the first axis direction.

10. The thermoelectric module according to claim 9, wherein

each of the terminals includes a first portion protruding from one of the electrodes toward the first edge portion, a second portion connected to a tip portion of the first portion and extending in the first axis direction between the electrode and the first edge portion, and a third portion protruding from the second portion toward the first edge portion,

the first terminal and the third terminal are arranged on one side of a center of the substrate and the second terminal and the fourth terminal are arranged on the other side of the center of the substrate in the first axis direction, and

the second portion of each of the first terminal, the second terminal, the third terminal, and the fourth terminal protrudes from the tip portion of the first portion toward the center of the substrate.

11. An adjustment method of a thermoelectric module that includes a plurality of electrodes arranged on a surface of a substrate and a plurality of thermoelectric elements respectively connected to the plurality of electrodes, and that generates electrical energy distributed to a first load and a second load, the method comprising:

calculating power consumption indicating electrical energy distributed to the second load on the basis of a voltage applied to the second load;

calculating a temperature of an end surface on a high temperature side and a temperature of an end surface on a low temperature side of the thermoelectric module on the basis of thermal resistance of the thermoelectric module, a temperature of a heat source that heats the thermoelectric module, and a temperature of an atmospheric space around the thermoelectric module;

calculating power generation output indicating the electrical energy generated by the thermoelectric module on the basis of the temperature of the end surface on the high temperature side and the temperature of the end surface on the low temperature side; and

calculating effective output indicating electrical energy distributed to the first load on the basis of the power consumption and the power generation output, wherein

an optimum voltage applied to the second load is determined on the basis of a plurality of kinds of the effective output calculated by sequential changing of the voltage applied to the second load.